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亚音叶型前缘形状对附面层参数影响
  • ISSN号:0253-231X
  • 期刊名称:《工程热物理学报》
  • 时间:0
  • 分类:V235.1[航空宇航科学与技术—航空宇航推进理论与工程] O357.52[理学—流体力学;理学—力学]
  • 作者机构:[1]National Key Laboratory of Science and Technology on Aero-Engine Aero-Thermodynamics, School and Energy and Power Engineering, Beihang University Beijing 100083, China, [2]Faculty. of Enviromnent and Technology, University of the West of England, Bristol BSI6 1Q Y, United Kingdom, [3]Computer Scienceand Engineering Department, Science & Technology Facilities Council (STFC), Daresbury Laboratory, Warrington WA4 4AD, UK
  • 相关基金:This work was supported by the National Natural Science Foundation of China (Nos. 11302012, 51420105008, 51476004, 11572025 and 51136003) and the National Basic Research Program of China (No. 2012CB720205). The compu- tational time for the present study was provided by the UK Turbulence Consortium (EPSRC grant EP/L000261/1) and the simulations were run on the UK High Performance Com- puting Service ARCHER. We also would like to acknowledge the University of the West of England for hosting the first author to carry out the initial simulation work.
中文摘要:

The efficiency and mechanism of an active control device ‘‘Spark Jet' and its application in shock-induced separation control are studied using large-eddy simulation in this paper.The base flow is the interaction of an oblique shock-wave generated by 8° wedge and a spatially-developing Ma = 2.3 turbulent boundary layer.The Reynolds number based on the incoming flow property and the boundary layer displacement thickness at the impinging point without shock-wave is20000.The detailed numerical approaches were presented.The inflow turbulence was generated using the digital filter method to avoid artificial temporal or streamwise periodicity.The numerical results including velocity profile,Reynolds stress profile,skin friction,and wall pressure were systematically validated against the available wind tunnel particle image velocimetry(PIV) measurements of the same flow condition.Further study on the control of flow separation due to the strong shock-viscous interaction using an active control actuator ‘‘Spark Jet' was conducted.The single-pulsed characteristic of the device was obtained and compared with the experiment.Both instantaneous and time-averaged flow fields have shown that the jet flow issuing from the actuator cavity enhances the flow mixing inside the boundary layer,making the boundary layer more resistant to flow separation.Skin friction coefficient distribution shows that the separation bubble length is reduced by about 35% with control exerted.

英文摘要:

The efficiency and mechanism of an active control device "'Spark Jet" and its application in shock-induced separation control are studied using large-eddy simulation in this paper. The base flow is the interaction of an oblique shock-wave generated by 8° wedge and a spatially-developing Ma = 2.3 turbulent boundary layer. The Reynolds number based on the incoming flow property and the boundary layer displacement thickness at the impinging point without shock-wave is 20000. The detailed numerical approaches were presented. The inflow turbulence was generated using the digital filter method to avoid artificial temporal or streamwise periodicity. The , merical results including velocity profile, Reynolds stress profile, skin friction, and wall pressure were sys- tematically validated against the available wind tunnel particle image velocimetry (PIV) measure- ments of the same flow condition. Further study on the control of flow separation due to the strong shock-viscous interaction using an active control actuator "'Spark Jet'" was conducted. The single-pulsed characteristic of the device was obtained and compared with the experiment. Both instantaneous and time-averaged flow fields have shown that the jet flow issuing from the actuator cavity enhances the flow mixing inside the boundary layer, making the boundary layer more resis- tant to flow separation. Skin friction coefficient distribution shows that the separation bubble length is reduced by about 35% with control exerted.

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期刊信息
  • 《工程热物理学报》
  • 中国科技核心期刊
  • 主管单位:中国科学院
  • 主办单位:中国工程热物理学会 中国科学院工程热物理研究所
  • 主编:徐建中
  • 地址:北京2706信箱
  • 邮编:100080
  • 邮箱:xb@mail.etp.ac.cn
  • 电话:010-62584937
  • 国际标准刊号:ISSN:0253-231X
  • 国内统一刊号:ISSN:11-2091/O4
  • 邮发代号:2-185
  • 获奖情况:
  • 中国期刊方阵“双效”期刊
  • 国内外数据库收录:
  • 美国化学文摘(网络版),荷兰文摘与引文数据库,美国工程索引,日本日本科学技术振兴机构数据库,中国中国科技核心期刊,中国北大核心期刊(2004版),中国北大核心期刊(2008版),中国北大核心期刊(2011版),中国北大核心期刊(2014版),中国北大核心期刊(2000版)
  • 被引量:21026